Fluid dosing device



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' w. M. VENABLE FLUID DOSING DEVICE Filed June 11, 1942 April la, w44.

w. M. vl-:NABLE 2,346,801

FLUID DOSING DEVICE Filed June 11, 1942 l 3 Sheets-Sheet 2 2. i l f AAA 4g INVENTOR Willi-m M. Venabze April 18,' 19M( w. M. VENABLE 2,346,801

FLUID DOSING DEVICE 5 Sheets-Sheet 3 Filed June 11, l194.2

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In 1408 1.06 l104 S+ u lo? I provide a metal block Patented Apr. 18, 1944 UNITED STATES PATENT OFFICE i 2,346,801 FLUTD DosrNG DEvTcE William Mayo Venable,

to Blaw-Knox Company,

poration of New Jersey Application June 11, 1942, Serial No. 446,569

Y (Cl. 184-7) 6 Claims.

This invention relates to devices for discharging measured amounts of fluid material to differm ent points of delivery. One application of the invention is the supply of fluidlubricant such as grease to a plurality of bearings but the invention also has utility in other fields.

This is in part a continuation of my copending application, Ser. No. 404,477 filed July 29, 1941, for Fluid dosing device."

Systems for distributing measured amounts of fluid at a plurality of spaced points have been known heretofore, including a plurality of "dosers connected to points of consumption, a pressure-applying means such as a pump, and a single supply conduit for the dosers (for example, my Patent 2,184,172) or a pair of supply conduits to which the pressure-applying means is connected alternately (for example, Dirkes Patent 1,995,342). It is an object of my invention to improve on known dosers for such systems, particularly in respect to the cost of manufacture, and the assurance of the proper sequence of operations to secure smooth and positive functioning. In particular, it is an object of my invention to provide a dosing device which can be made easily and quickly from a simple starting piece such as a block, by routine machining operations such as drilling.

In a preferred embodiment of the invention, of suitable material and appropriate size. block provides a measuring cylinder in which a floating piston reciprocates. A pair of holes generally at right angles cylinders for reciprocating piston valves. Interconnecting passages, inlets and outlets communieating with said measuring vand valve cylinders are arranged to cause automatic operation of the floating piston in opposite directions on applica-.- tion of pressure to fluid in the supply conduits successively followed by the release of the pressure. The several cylinders, passages, inlets and outlets may be convenientlyP formed by drilling into the block normal to the faces thereof and plugging the holes as may be necessary.

In one form of the invention, the doser is adapted to deliver measured charges of fluid to a substantial number of outlets successively in a single stroke of the floating piston. In this embodiment, I provide the measuring cylinder with a plurality of outlet passages spaced therealong and the floating piston reciprocable in' the cylinder with an annular groove adapted to place each of the passages successively in communication with a charge of fluid ahead ofthe to said cylinder provide A hole drilled through the adjacent the points Pittsburgh, Pa., assignor Pittsburgh, Pa., a corpiston, during a predetermined portion ofthe travel of the piston. Movement of the piston is effected by delivering fluid under pressure behind it.

Two species of this embodiment are shown, in one of which the piston in the measuring cylinder is moved alternately in one direction and the other by fluid pressure only, and in the other species the piston in the measuring cylinder is moved in one direction only by fluid pressure and in the opposite direction by a spring, when the fluid pressure is suiliciently reduced.

In the first-mentioned species flow of fluid from the measuring cylinder and the supply of iiuid thereto are governed by two control valves of the piston type in much the same manner as disclosed in my Patent 2,341,249 granted on a copending application but with this difference in said copending application, the valve cylinders are parallel with the measuring cylinder, being bored from the same face of the block, while in the rst mentioned species disclosed herein the valve cylinders are bored from a face or faces of the block in general at right angles to that from which the measuring cylinder is bored.

In this first species each of the two valves consists of a bore, preferably cylindrical, with several ports entering its wall, and a piston or pistons with close fitting heads sliding therein. These bores will be referred to as valve cylinders. They are parallel with one another, 'and in general at right angles to the direction of the axis of the measuring cylinder. The valve pistons are reciprocated within the valve cylinders by supplying and releasing pressure, alternately, from two different supply lines, as will be more fully described hereafter. The advantage of having the valve cylinders at right angles to the general direction of the axis of the measuring cylinder in this species will be apparent when this species `is described in detail.

In another form of the invention, the full charge displaced by a single stroke of the piston is delivered to one of only two outlets. Usually the dosers will be scattered in various locations of consumption, each doser supplying one point on each piston stroke, or to points alternately.

Further details, novel features and advantages of the invention will become apparent during the following complete description and explanation thereof referring to the accompanying drawings illustrating the embodiments outlined above. In the drawings,

Figure 1 is a longitudinal central section through one embodiment, with vparte; in elevation;

Figure 2 is a longitudinal section taken substantially along the plane of line II-II of Figure 1; line I-I of Figure 2 illustrates the plane onv which the section ofl Figure 1 is taken;

Figure 2A is a partial section taken along the plane o1' line IIa-IIa of'Figure 1;

Figures 3, 4 and 5 are transverse sections taken respectively along the plane of lines III-III, IV-IV and V-V of Figure 1;

Figure 6 is a side `elevation of a modified form' of dosing device with parts in section;

Figure 7 is a longitudinal section through the measuring cylinder of the device shown in Figure 6, but off-set therefrom outside said cylinder to pass through four outlets thereof, two on each of the opposite sides, the plane of section being indicated by line VII-VII of Figure 6;

Figure 8 is a side elevation of the discharge piston for the modified form of dosing device;

Figure 9 is a plan view of a further embodiment of the invention;

Figure 10 is a section therethrough on the plane of line X-X of Figure 9;

Figure 11 is a section taken along the plane of line IUI-XI of Figure 10;

Figure 12 is a bottom plan view with parts in section.

Referring now in detail to the drawings and, for the present, to Figures 1 through 5, the preferred embodiment indicated generally at III comprises a block of metal or other suita-ble material bored longitudinally to provide a measuring cylinder I2. A piston I3 is reciprocable in the cylinder I2 and is composed of sections |4 and I5. 'I'his piston may be made in a single piece, but it is preferred to make it in several pieces (four -being shown) because by so doing itwill be less likely to bind in cylinder I2 because of its length,

in case I2 is not perfectly straight, and therefore closer fits are possible without extreme precision in' the-machining of parts. An annular groove I8 is formed in the piston I3 adjacent` the middle thereof.

The ends of the cylinder I2 are closed by plugs I1 and I8, the latter having a hole therethrough admitting an indicator stem I9 extending axially from the cylinder. A cage is formed on the plug I8 to protect the stem I 9 when extended.

The block is bored transversely to provide valve cylinders 2| and 22. Inlet pipe connections 23 and 24 are threaded into opposite ends of the cylinders and the other ends thereof are closed by screw plugs 2Ia and 22a. Piston valves 25 and 26 are reciprocable in the cylinders 2| and 22. A piston with two heads, 25 and 21, and a circumferential groove therebetween, is reciprocable in valve cylinder 2| and a similar piston with two heads 26 and 28 in valve cylinder 22. Each piston may be made in the form of aisingle piece, or of two abutting pieces, as desired. The pistons have stems projecting beyond heads 21 and 28 to provide stops adapted to engage the plugs 2| a and 2lb respectively, so as to limit the motion of the heads. f

The drawings show the valve pistons as consisting of a stem with two heads. These may be made in two parts, if desired, as in operation there never is tension in the stem between them. By doing this slightly less precision is required in boring the valve cylinders, to prevent binding.

Spaced parallel longitudinal passages 29 and 38 communicate with the valve cylinder 2|. Cross passages 3| and 32 communicate with the pas- 75 sages 28 and 38 respectively, and the cylinder I2 adjacent one end thereof. A connection is thus provided between one end of cylinder I2 and the valve cylinder 2|. While two longitudinal and cross passages make up the connection, this is merely for convenience in manufacturesince the two parallel passages function alternately, and a single passage of proper size would serve equally well. Similarly. longitudinal passages 33 and 34 communicate with the valve cylinder 22 and cross passages 35 and 38 communicate with the passages 33 and 34 respectively and the cylinder I2 near the other end.

'I'hree passages. 31, 38 and 38, are drilled parallel to one another longitudinally through an oil'- set portion 40 of the block, as shown In section in Figure 4. By holes 4| and 42, drilled at right angles to a face of the block, at one end of each, the cylinders 2| and 22 connect with passage 38: by holes 43 and 44 the other ends of cylinders 2| and 22 communicate with passage 38; by holes 45A and 46 the middle portions of cylinders 2| and 22 communicate with passage 31. -The ends of passages 31, 38 and 88 are plugged. A plurality of passages 41a. 41h, 41e, etc., intersect the passage 31 and the cylinder I2 at points convenient method of manufacture but, since the only purpose thereof is to provide communication between the passage 31 and the cylinder I2, they could be replaced by a single such passage and a longitudinal groove in the wall of the cylinder I2. 'Ihe passages 41a, 41b, etc., are spaced apart by a distance less than the Width of the groove I6 in the piston I3 so that the latter is always in communication with the passage'31 through one or another of the passagesv 41a, 41h, etc.

Outlet passages 48 are spaced along the cylinder I2 and are preferably staggered on opposite sides of the cylinder as best shown in Figure 2A. The openings from the Cylinder I2 into the passages 48 are all overlapped by the piston I3 or its groove I5 in all positions of the piston. Outlet pipes 49 may be threaded into tapped enlargements of the passages 48 as shown in Figure 5, and extend to the several points to which fluid is to be delivered, only those on the opposite side ofthe cylinder from the point of view being shown in broken lines in Figure 1. The distance between centers of passages successively communicating with piston groove I6 is equal to the width of the groove as clearly shown in Figure 2A.

It will be apparent that the several cylinders and connecting passages may easily be provided by simple drilling operations on a' solid block of metal, atright angles to the faces of the blocks, the drilled passages being plugged on the outside, where necessary, as indicated in the drawings. .This feature of the invention makes possible the manufacture of the device at a relatively low cost.

The chief features of the invention thus far described with reference toFigures 1 to 5 are also present in the device shown in Figures 6 to 8, still to be described, and are independent of the means employed for moving the piston lengthwise of the cylinder, which might be done by grease pressure as will be described hereafter, or by hand power as in the ordinary grease gun.

operation of the multipledose delivering feature before describing the operation of either valve mechanism, to facilitate a clear understanding of this leading feature, using therefor Figure 1, and assuming that the valve pistons and 26 are so positioned as to permit grease from the right-hand end of the cylinder I2 (as shown) to flow freely through passages 36, 33, 46, 31 and 41a, 41D, etc., to the groove I6 in the piston I3.

Movement of the piston I3 toward the right forces grease from the right-hand end of the cylinder I2 through the several passages just enumerated and the groove I6 in the piston, to the outlet passage 43 at the extreme left as shown most rclearly in Figure 2A. The amount of grease delivered from the first outlet passage will be equal to the cross-sectional area of cylinder I2 times the distance between consecutive outlet passages 28. As the piston continues to move. similar doses are delivered through the remaining outlet passages successively.

In explaining a complete cycle of operationof the preferred embodiment described above, it will be assumed that the discharge piston and valve pistons are in positions in which they are illustrated and that all the cylinders and pasl sages are full of fluid to be delivered, such as grease.

With the valve pistons in their illustrated positions, the device may be operated by supplying fluid under pressure to the inlet 24. This displaces valve piston 2d downwardly as viewed in Figure 2. This movement of the valve piston forces a small amount of grease through passage it into passage 33, and thence into valve cylinder 2t and the other end of supply. pipe 23, there being no pressure applied at the pump end of the pipe 23. The movement of piston head 23 also establishes communication between passages 33 and de through the valve cylinder 22 and thus permits the discharge of fluid from the right hand end of dosing cylinder I2, as seen in Fig. 1, into the annular space It. Shifting of the valve piston heads 28 and 23 opens the passage 4t and connects the cylinder end shown at the right in Figure 1 with the passage 31 and the middle portion of cylinder l2. Shifting of valve piston head 2t also opens the passage 42 and permits fluid to flow through passages 38 and 4I into cylinder 2I and to shift the valve piston therein. Movement of valve piston heads 21 and 25 forces some more iiuid back into the pipe 23. Movement of piston head 21 past the opening of passage 38 into valve cylinder 2i permits iluid to flow through the passages 30 and 32 into cylinder I2 adjacent plug I1. Movement of valve piston head 21 also interrupts communication between valve cylinder 2l and passage 29.

The entrance of fluid into the cylinder I2 between the plug I1 and the piston I3 displaces the latter to discharge the fluid between the piston and the block I8. This luld is permitted to flow through the passages and 33 into the valve cylinder 22 between the heads 21 and 23 of the valve piston 26. The uld is then free to flow through passage 46 into passage 31 and thence through passages 41a., 41h, etc., into the groove I6 in the piston I3, which makes connection with each of the outlet passages 4B in succession.

As the piston I3 moves along the cylinder I2, it remains in communicatiom'for a predetermined time, with each of the outlet passages 4B.

Since the groove I6 is supplied with iluid underV pressure at all times through the passages 41a, 41h, a measured quantity of fluid flows through each outlet passage 48 and connecting pipe 49 during the time it is in communication with the groove. It is thus possible, by a. single device, to

14 communicating charge of fluid from opposite deliver measured amounts of :luid to a considerable number oi points of use.

When the piston I3 has reached the limit of its movement, nothing further happens until iluid under pressure is delivered through the inlet 23 after relief' of the pressure on the inlet 24. When this occurs, the valve pistons in cylinders 22 and 2I are displaced successivelyin the same manner as previously described but in the opposite direction. As a result, fluid flows from inlet 23 through passages 43, 39 and 44 ,into the valve cylinder 22, thence through passages 34 and 38 into the right hand end of measuring cylinder I2. Leftward movement of the piston I3 then forces fluid through passages 3i and 29 into the valve cylinder 2i between heads 21 and 23 of the valve piston 25, thence through passages d, 31, 41a, Mb, etc., into the groove I6 in the discharge piston from which it flows successively out of the outlet passages 48 into the pipe connections 48.

The piston valves and connecting passages controlling the supply of iluid to and the disends of the measuring cylinder are described and claimed broadly in my copending application, Serial No. 404,476 led July 29, 1941, for Fluid dosing device, although the exact arrangement of valves shown herein is not described in said application. Specifically, the principal difierence is that the valve cylinders 2l and 22 extend transversely of the measuring cylinder I2 instead of parallel thereto as in the copending application. The former arrangement is particularly advantageous because it greatly facilitates drilling operations necessary in the manufacture of the dosing device.

Figures 6 through 8 illustrate a modification of the invention whereby it is adapted for a dosing device oi the general type shown in my Patent 2,184,172. This form of the invention includes a block or body 6U bored longitudinally to provide a cylinder Si. The-ends of the cylinder are closed by screw plugs 62 and E3. A piston '54 is reciprocable in the cylinder 6I and is normally urged to its uppermost position by a compression spring 65. The spring bears on the screw plug G3 and on a shoulder- 36 in a longitudinal bore B1 through the piston. The bore 61 has a portion t@ of reduced diameter in which a valve piston 69 is reciprocable. A screw plug 'Ill closes the upper end of the bore 58 and a compression spring 'II is disposed therein bearing on the bottom of the valve piston 69 and on a bush; ing 12 threaded into the bore 63 adjacent the shoulder 66. An inlet pipe connection 13 is threaded into a tapped enlargement of a passage with the Qylinder 0I. The piston 64 has anannular recess 15 which is in communication with the passage 14 in all positions of the piston. An angular passage 16 connects the recess 15 and the upper end of the bore 6B. Another angular passage 11 extends inwardly from the upper end of the piston 64 and into the bore 63 therethrough at a point below the bottom of the valve piston 89 when it is in its uppermost position.

Outlet passages 18 from the bore 6I are spaced therealong preferably in staggered relation on opposite sides and have tapped enlargements to receive delivery pipe connections 19.

An annular groove is formed inthe piston 64 and is positioned so that it will come into registry with the passages 18 successively as the piston moves downwardlyffrom its uppermost p0- sition. Radial holes 8| drilled through the wall of the piston 84 provide communication between the interior thereof and the groove 88.

In explaining the operation of the modified form of the invention, it will be assumed that the parts are in their illustrated positions and that the entire device is filled with grease or other fluid to be delivered. 'I'he device is operated by supplying iiuid under pressure through the inlet pipe 13 through the passage 14. 'Ihe fluid flows through the recess 15 in the piston and the angular passage 18 into the bore 88 above the valve piston 88. The latter is thereupon displaced downwardly compressing the spring 1| and forcing a small amount of fluid through holes 8| into groove 88, the upper outlet 18 and pipe connection 18 to the point of use. When the valve piston 68 clears the lower end of passage 11 uid is admitted through the latter through cylinder 8| above the piston 84. The piston 88 is thereby forced downwardly.

Downward movement of the piston 84 iluid inside the piston and in the lower causes end of the cylinder 8| to be displaced through holes 8|.

and the groove 88 into the outlet passages 18 successively. It will be observed that these passages are so positioned that the groove 88 in the piston will be in communication with at least one of the passages at all times. The fluid displaced by the descent of the piston is thus discharged successively to the several points ofvuse through the pipe connections 18a, 18h, 19e, 18d, 18e and 18).

When the piston 84 has reached the limit of its downward travel and the pressure on the inlet connection 18 is relieved, the spring 1| restores the valve piston -88 to its illustrated position. This provides a by-pass for the fluid 'between the piston and the screw plug 62 whereupon the spring 85 forces the piston upwardly, thus displacing the fluid thereabove through the passage 11 and into the interior of the piston and the portion of the cylinder 6| therebelow. The device is then readyy for -a second operation by the application of pressure to the inlet connection 13.

Figures 9 through 12 illustrate a further form of the invention similar to that of Figures l through 5 in that it includes a pair of piston valves for causing operation of the main piston solely by hydraulic pressure but differing therefrom in that the device oi Figures 9 through 12 is adapted to deliver iluid alternately to one of only two consumption points. In this latter respect, the device of Figures 9 through l2 is generally similar to that disclosed in my copending application, Serial No. 404.476 referred to above. In this form of the invention, a block -82 of suitable metal has a bore therethrough forming a measuring cylinder 83 one end of which is closed by plug 84. A floating piston 85 is reciprocable in the cylinder 83 and has a stem 88 extending axially thereof. A cage 81 has a base 88 threaded into the other end of the cylinder 83, which is drilled to receive the stem 86 and provided with a sealing gland 88a. A plug 88 threaded in the upper end of the cage provides an adjustable stop ior engagement 4by the stem 88 to limit movement of the piston. The stem 88'is visible and acts not only as a stop, but also as an indicator, moving Whenever a dose is being delivered.

Valve cylinders 88 .and 8| are drilled through the block 82. They are parallel to each other and preferably lie in a plane parallel to the axis o1 the cylinder 88.

In the illustrated embodiment, u

furthermore, the plane determined by the axes oi the valve cylinders is normal tothe plane normal to the axis of the measuring cylinder 88. Fluid-supply pipes 82 and 88 are threaded into opposite ends o1' the valve cylinders and the other ends thereof are closed by plugs 84. Pistons 8l and," are reciprocable in the valve cylinders, each including spaced heads 81 and 88 connected by a reduced portion 88, and a stem |88 projecting i'rom one end adapted to engage one o1' the plugs 84 to limit travel o1 the pistons in one di.- rection. Movement of the pistons in the other direction is limited by bushings 88a and 8|a held in the valve cylinders by the pipes 82 and 88, or by the pipe ends themselves. Since the heads 81 and 88. the only parts of the valves having contact with the valve cylinders, have only a llmited travel therein, it is not necessary for the valve cylinders to be accurately finished through their entire length but only in those portions within the range of movement of the heads.

Interconnecting passages 8| and |82 extend between the valve cylinders adjacent the ends thereof. These passages may be formed by drilling from a face of the block 82 and plugging the ends of the holes thus formed.

Passages |83 and |84 extend from opposite ends of the cylinder 88 to the adjacent valve cylinder.

the block and plugging the holes. It vlill tbe noted that these passages may be very s or Outlet passages 85 and |86 are drilled into the block, preferably though they may equally well be drilled from opposite ends. Pipes |81 and |88 are threaded into the outlet passages and extend to the points to which fluid is v device with the parts in the popplied to the uid is conpassages |83 and ||8 by way oi'l valve cylinder 88, thus open- I may be used on either ing a continuous passage for a dose to be delivered from cylinder 83 to outlet passage 406.

Motion of the head 99 past the opening 02 also admits huid to the valve chamber Si, at the right hand end. Since there is frictional resistance in passage ill?, however, the pressure in the `right hand end of cylinder 9i will be less than in the right hand end of cylinder tit; and the piston in cylinder 9i will not normally move until that in cylinder 90 has completed its stroke, opening the discharge ports for the dose. But as soon as the piston in cylinder 9@ has completed its stroke the piston in cylinder 9i will move, establishing communication between passage im and the passage tilt and blocking communication between passage iiil and inlet t3. The motion of the piston in cylinder @l will force a small additional amount of iiuid back into the pipe 93, slightly increasing the back pressure there.

Fluid'pressure will then cause the motion of piston tu and force a dose from cylinder 83 to the outlet pipe it.

The length oi motion of piston t5 and consequently the size of the dose, may be adjusted by means oi the plug 89.

`When it is assured that all the dosing devices on the same pressure pipe line have operated, it is customary to relieve the pressure'at the pump end of thepipe line, so as to reduce leakage; and after a suitable interval of time to apply pressure to the other pipe line, for the purpose of discharging another set oi doses. The operation of the device is the same as that just described except that the order in which the' operations of the valves take place and the direction of their motion are reversed; and the dose is applied by motion oi the piston 95 in the opposite direction. v

It will be apparent from the foregoing that the form of the invention shown in Figures 9 through l2 operates automaticallyfin response to the application of pressure to the iuid in the inlets alternately, and the relief thereof, todeliver measured amounts oi fluid from the outlets alternately.

It will also be apparent from the foregoing description and explanation -that the invention provides a highly effective dosing device capable of delivering measured amounts of iluid to a' considerable number of diilerent delivery points. such as bearings or the like. The device in the form illustrated in Figures 6 to 8 is applicable to a system utilizing a single pressure pipe, but

pipe line of alsystem utilizing two pressure pipes. As illustrated it contains features in common 4with my Patent 2,184,172. The device illustrated in Figures 1 to 5 ,and that illustrated in Figures 9 to 12A are applicable only to two-pipe systems, and contain two valve chambers and pistons which are similar in construction and function to the valve cham- -bers and pistons described and claimed in my copending application, Ser. No. 404,476. In both cases, the structure of the dosing device and its component parts is relatively simple so that manuiacturing costs are relatively low. It is obvious that there are advantages in the ability to serve a plurality of delivery points from'a single dosing device, as well as in the provision of a plurality oi dosing devices. one for each point of delivery. shown in Figures 9 through l2 is characterized by a high degree of simplicity so that it may and at relatively lowl cost. All the cylinders. passages and outlets are formed by drilling into f the portions of the the block normal to the faces thereof. The passages connecting the valve cylinders to the measuring cylinder are quite short, providing direct communication with only an insignificant pressure dropped therein. As already pointed out, valve cylinders actually 'Y traversed by the 'valve pistons are quite short,

" a series of portsthrough said be manufactured easily `a series of ports thus keeping to a minimum the extent of the cylinder surface required to be accurately iinished. All the passages communicating with the measuring cylinder or valve cylinders are short` and direct, .insuring easy ow of fluid therethrough. The valve ports are opened fully under minimum operating pressure. As a' result, only a slight difference between the pressures in the `two supply lines is necessary to cause lthe device to execute a dosing cycle. This is particularly important in installations where long supply lines 'are involved because it reduces the degree oi pressure which it is necessary to apply at the iiuid source.

Although I have illustrated and described but a few preferred embodiments of the invention, it will be recognized that changes in the constructions disclosed may be made without departing from the spirit of the invention or the scope of the appended claims.

I claim: a.

l. In a uid dosing device, the combination of a cylinder containing the material 'to be dosed. a series of ports through said cylinder wall at spaced intervals therealong, for delivery of doses, a piston with a' circular annular groove slidable in said cylinder, said piston and groove being dimensioned to cover all of said ports in any position which said piston may occupy, said groove being sumciently wide to extend over at least a part oi two ports at a time, passages outside of said cylinder extending from near'eachend'wthereof to the middle portion of said cylinder wall and registering with said piston groove in all positions thereof. and valves for establishing and interrupting communication through said passages from either end or said cylinder.

2. In a iiuid dosing device. the combination of a cylinder containing the material to be dosed. cylinder wall at spaced intervals therealong, for delivery of doses, a piston with a circular annular groove slldable in said cylinder, said piston and groove being dimensioned to cover all oi said ports in any position which said piston may occupy, said groove being sufllciently wide to extendf'over at least a part of two ports at a time, and passages outside of said cylinder 'from near each end thereof to the middle portion of said cylinder registering with said piston groove in allpositions thereof, each of said passages including a cylinder having a piston valve reciprocable therein for opening and closing the passage, said piston valve cylinders being parallel to each other, and normal to the axis or said dosing cylinder.

3. In a iiuid dosing device, thecombination ol a cylinder containing the material to be dosed.

through said cylinder spaced intervals therealong, for delivery oi' doses,

-a piston with a circular annular groove slidablc in said cylinder, said piston and groove being dimensioned to cover all of said ports in any position which said piston may occupy, said groove being sumciently wide to extend over at Y least a part of two ports at a time,- passages outside of said cylinder from near each end thereof tothe middle portion of said cylinder wall regiswall at tering with said thereof,

cylinders and passages being drilled perpendicular to three planes another.`

4. In a duid-dosing device, ablock having a bore therein forming a dosingv cylinder, -a piston at right angles to one said passages. and

overlaps the connection pistons 'normally .being port of the cylinder of the actuated valve piston, opening communication between said -inlet and said one end ofV said one of admitting fluid therethrough cylinder to cause the valve move sequentially from the position to the rst-menadmit fluid to the other end of the dosing cylinder, and means extending between the ports in the valve cylinders and the points to whichuid is to be delivered for conto the other valve piston therein to o' the block, respectively. .Y i

6. The apparatus dened by claim 4 characterized by outlets each comprising solely a pasblock parallel to saiddosing cylinder and at right angles to said valve cylinders and communicating with the port in lone valve cylinder.

WILLIAM MAYO VENABLE. 

